Prolonged field bursts in the dentate gyrus: dependence on low calcium, high potassium, and nonsynaptic mechanisms.

1. The dentate gyrus has been proposed to be a gate for entry of neuronal activity into the hippocampus. This function would give it a critical role in the propagation of seizure activity in that region. The hallmark of epileptiform activity in the dentate itself, often referred to as "maximal dentate activation" (MDA), has not been reproduced previously in vitro. 2. With the use of rat hippocampal slices, bath [Ca2+] was decreased, and [K+] was increased concurrently to simulate conditions found during intense neuronal activity in vivo. Both evoked and spontaneous field bursts were observed in the dentate granule cell layer under these conditions. These bursts were similar to MDA, consisting of a prolonged negative shift in extracellular potential with large-amplitude population spikes. 3. In 0.5 mM bath [Ca2+], single stimuli applied to the perforant path could evoke prolonged field bursts in the dentate only when bath [K+] was > or = 9 mM. However, repetitive stimulation (10 Hz) of the perforant path could elicit similar dentate responses when bath [K+] was as low as 5 mM. 4. In 0.5 mM bath [Ca2+], interictal-type bursts appeared spontaneously in CA1 and CA3 when bath [K+] was > or = 5 mM but were lost when [K+] was > 9 mM. Spontaneous seizurelike activity in the dentate required a higher minimum bath [K+] (9 mM) and persisted at [K+] of 11 mM. 5. Stimulation-evoked field bursts in the dentate altered epileptiform activity in CA3. At bath [K+] insufficient to cause spontaneous CA3 bursts, CA3 was activated transiently when prolonged field bursts occurred in the dentate. At higher bath [K+] in which spontaneous CA3 bursts did occur, they were depressed during the dentate bursts. 6. Deletion of Ca2+ from the bath; the addition of 30 microM each of bicuculline methiodide, D,L-2-amino-5-phosphonopentanoate (AP-5), and 6,7-dinitroquinoxaline-2,3-dione (DNQX); or the combination of both manipulations did not block antidromically evoked or spontaneous prolonged field bursts in the dentate. Thus the mechanisms maintaining and propagating these events did not require fast amino acid-mediated synaptic transmission. 7. The concurrent alteration of [K+] and [Ca2+] required to produce prolonged field bursts in the dentate underscores the positive feedback relationship between neuronal excitation and extracellular ionic concentrations, whereas the ability of synaptic stimulation to trigger nonsynaptic seizurelike events such as these prolonged field bursts may be relevant to the transition from interictal to ictal activity in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nonsynaptic epileptogenesis in the mammalian hippocampus in vitro. II. Role of extracellular potassium

The role of extracellular K+ (K+o) in nonsynaptic epileptogenesis induced in the CA1 area of rat hippocampal slices by lowering [Ca2]o was studied with K+-selective microelectrodes (KSMs). Extracellular field potentials and [K+]o were recorded simultaneously with 1-2 KSMs in the CA1 stratum pyramidale. In slices perfused with an oxygenated standard physiological solution (containing 2 mM Ca2+), base-line [K+]o was stable for several hours. The washout of Ca2+o was accompanied by a gradual tonic rise of [K+]o. Spontaneous and stimulus-evoked maximal seizurelike events (SLEs) appeared when [K+]o was approximately 0.5 mM above the initial 5 mM base line. These changes were reversible in normal medium. When K+o was pressure ejected in the CA1 stratum pyramidale of spontaneously active slices, a local rise in [K+]o of approximately 0.5 mM was necessary to trigger a SLE. A similar apparent [K+]o "threshold" was associated with SLEs evoked by electrical stimulation. Increasing [K+] in the perfusing solution by small increments (1 mM) markedly enhanced SLEs frequency and velocity of spread and decreased the period of absolute refractoriness that succeeded each paroxysm. Similar changes occurred during periods of transient hypoxia. Small [K+] decreases in the perfusate had the converse effects. Spontaneous SLEs were associated with phasic increases in [K+]o. In simultaneous [K+]o recordings from two layers, these transients were largest (up to 3.5 mM above base line) and rose more steeply at the stratum pyramidale. Toward the outer dendritic layers they became smaller, slower in time course, and delayed in onset. We conclude that the main source for these [K+]o transients are the hippocampal pyramidal cell bodies, which discharge intensely during a SLE, and that excess K+o is spatially dispersed around the discharge zone of the paroxysm. [K+]o continued to rise, though at a slower rate, throughout the course of a SLE. Following SLE termination, [K+]o decayed slowly to base line. The invasion of a CA1 region by a propagating SLE was preceded quite often by a slow rise in [K+]o. A sudden transition to a steeply rising [K+]o marked the explosive recruitment of this region into the discharge zone of the spreading paroxysm. The total (tonic and phasic) increase in [K+]o during SLEs did not surpass a maximal level of approximately 9 mM, which was the ceiling level of [K+]o in low [Ca2+]o. However, when spreading depression occurred, [K+]o rose up to 30-40 mM for several minutes. Spreading depression rarely appeared spontaneously despite the recurrence of SLEs, but could be provoked by repetitive electrical stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Low extracellular magnesium induces epileptiform activity and spreading depression in rat hippocampal slices

The effect of low extracellular Mg2+ concentration ([Mg2+]o) on neuronal activity was studied in rat hippocampal slices. After 20-40 min of perfusion with Mg2+-free medium, when [Mg2+]o declined to approximately 0.1-0.4 mM, spontaneous field potentials developed in the CA1 and CA3 regions, but not in the dentate gyrus. In the CA3 pyramidal cell layer, these potentials consisted of repetitive (0.3-0.5 Hz), 40- to 120-ms-long positive deflections (2-5 mV) with superimposed population spikes. In the stratum (str.) pyramidale of the CA1 region, positive-negative deflections (less than 3 mV) lasting for 30-80 ms were observed, which occurred with a frequency of 0.3-0.5 Hz. In some cases, longer lasting and rapidly recurring events were also observed. In CA3 pyramidal cells, the intracellular correlates of the field potential transients were 20- to 30-mV paroxysmal depolarization shifts (PDS) with superimposed bursts of action potentials, followed by large (greater than 10 mV), 500- to 1,200-ms-long afterhyperpolarizations (AHP). In contrast, pyramidal neurons of the CA1 area did not show PDSs; instead, sequences of excitatory postsynaptic potentials (EPSPs)/inhibitory postsynaptic potentials (IPSPs) accompanied the transient field potential changes. Occasionally, spontaneous EPSPs/IPSPs, occurring with high frequencies, could also be observed in CA1 without any field potential transients. In both hippocampal regions, the epileptiform activity evolved without significant alterations in the resting membrane potential (RMP) and input resistance (RN) of the neurons, although a 2- to 5-mV reduction in action potential threshold was noted. The spontaneous activity in Mg2+-free medium was readily suppressed by raising the extracellular Ca2+ concentration ([Ca2+]o) from 1.6 to 3.6 mM. The perfusion of 10-30 microns DL-2-amino-5-phosphonovaleric acid (2-APV), an antagonist for the glutamate receptors of the N-methyl-D-aspartate (NMDA) type, also attenuated or reversibly blocked the spontaneous activity. Surgical isolation of area CA1 from CA3 ceased the occurrence of the transients in CA1 but not in CA3. The synaptic input/output curves were shifted to the left in the absence of [Mg2+]o. Threshold intensity for eliciting population spikes was 50-75% of that in normal medium. Paired-pulse facilitation was still present near threshold, but was reduced at higher stimulus intensities. Decreases in [Ca2+]o, produced by repetitive stimulation (20-Hz/5-10 s) of the Schaffer collateral/commissural pathway and monitored with ion-selective microelectrodes in the CA1 region, were enhanced in Mg2+-free medium.(ABSTRACT TRUNCATED AT 400 WORDS)     

Chronic hyperglycaemia increases neuronal sensitivity to high potassium in hippocampal slices from streptozotocin-treated diabetic rats

The chronic hyperglycaemia associated with diabetes mellitus increases susceptibility to epileptiform-like activity in the central nervous system. Changes in extracellular potassium levels directly influence neuronal excitability and significantly one of the major regulators of extracellular potassium, the Na-K ATPase, is known to be down-regulated by chronic hyperglycaemia. The sensitivity of hippocampal slices, from rats made diabetic for 2-3 weeks with streptozotocin, to increases in the extracellular potassium concentration ([K+]o) was, therefore, investigated. Raising [K+]o to 10 mM increased the number of orthodromically-evoked population spikes (PSs) in area CA1. This recruitment was significantly greater in hippocampal slices from diabetic rats, which also exhibited significantly more spontaneous activity. These findings confirm a diabetes-dependent increase in sensitivity of central neurones to changes in [K+]o and may help to explain the increased susceptibility to epileptiform activity in this disease state.     

Different responses of CA1 and CA3 regions to hypoxia in rat hippocampal slice

1. To study the effects of brief periods of hypoxia on cellular functions in the rat hippocampal slice, extracellular and intracellular recordings were made from pyramidal neurons, and interstitial potassium activity ([K+]o) was measured in the pyramidal cell layers. Slices were perfused in an interface chamber at 36-37 degrees C with medium containing 8.5 mM [K+]o. Hypoxia was induced by switching the overflow gas from O2-CO2 to N2-CO2. 2. Brief periods of hypoxia (5-60 s) produced electrographic seizures with typical tonic and clonic components in 53% of 293 slices that generated spontaneous interictal bursts. Hypoxia-induced seizures were usually initiated in and restricted to the Ca1 region; only 2.5% of these slices generated seizures in CA3. In contrast to the CA1 region, the CA3 region could undergo spreading depression during hypoxia. The probability of seizure generation in CA1 was increased with increasing duration of hypoxia and was greatly reduced by lowering the bath temperature a few degrees. 3. [K+]o gradually increased in the CA1 and CA3 cell layers during the 20 s leading up to an hypoxia-induced seizure. [K+]o rose to approximately 9.8 mM (from a base line of 8.5 mM) in CA1 just before a seizure and to 11.4 mM during the seizure. After hypoxia, [K+]o reached a higher level in CA1 than in CA3, regardless of whether 1 microM tetrodotoxin was present to eliminate differences in cell firing in the two regions. CA1 pyramidal cells and glia gradually depolarized by several millivolts during and after hypoxia; no initial hyperpolarizing phase was detected. 4. Burst input from CA3 was necessary for hypoxia-induced seizures. The frequency and intensity of spontaneous burst-firing in CA3 remained steady in the period leading up to a CA1 seizure episode. In contrast, the intensity of synaptically driven bursts in CA1 grew markedly just before seizure onset. N-methyl-D-aspartate (NMDA) receptors participated in the crescendo of increasingly synchronous activity in CA1, because the competitive NMDA receptor antagonist, D-2-amino-5-phosphonovaleric acid (D-APV, 30 microM), stereoselectively reduced seizure intensity. 5. Hypoxia-induced seizures were followed by a depressant phase, which was manifested most prominently by a prolonged (up to several minutes) reduction in the frequency and intensity of burst-firing in the CA3 region, hyperpolarization of CA1 neurons, and undershoot of [K+]o. In normal (3.5 mM) [K+]o, synaptically driven population spikes in CA1 were only reduced in amplitude by hypoxia; hypoxia did not induce seizures in 3.5 mM [K+]o.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sodium-potassium pump inhibitors increase neuronal excitability in the rat hippocampal slice: role of a Ca2+-dependent conductance

We have used the rat hippocampal slice preparation as a model system for studying the epileptogenic consequences of a reduction in neuronal Na+-K+ pump activity. The cardiac glycosides (CGs) strophanthidin and dihydroouabain were used to inhibit the pump. These drugs had readily reversible effects, provided they were not applied for longer than 15-20 min. Hippocampal CA1 pyramidal cells were studied with intracellular recordings; population spike responses and changes in extracellular potassium concentration ([K+]o) were also measured in some experiments. This investigation focused on the possibility that intrinsic neuronal properties are affected by Na+-K+ pump inhibitors. The CGs altered the CA1 population response evoked by an orthodromic stimulus from a single spike to an epileptiform burst. Measurements of [K+]o showed that doses of CGs sufficient to cause bursting were associated with only minor (less than 1 mM) changes in resting [K+]o. However, the rate of K+ clearance from the extracellular space was moderately slowed, confirming that a decrease in pump activity had occurred. Intracellular recording indicated that CG application resulted in a small depolarization and apparent increase in resting input resistance of CA1 neurons. Although CGs caused a decrease in fast gamma-aminobutyric acid mediated inhibitory postsynaptic potentials (IPSPs), CGs could also enhance the latter part of the epileptiform burst induced by picrotoxin, an antagonist of these IPSPs. Since intrinsic Ca2+ conductances comprise a significant part of the burst, this suggested the possibility that Na+-K+ pump inhibitors affected an intrinsic neuronal conductance. CGs decreased the threshold for activation of Ca2+ spikes (recorded in TTX and TEA) without enhancing the spikes themselves, indicating that a voltage-dependent subthreshold conductance might be involved. The action of CGs on Ca2+ spike threshold could not be mimicked by increasing [K+]o up to 10 mM. A variety of K+ conductance antagonists, including TEA, 4-AP, Ba2+ (in zero Ca2+), and carbachol were ineffective in preventing the CG-induced threshold shift of the Ca2+ spike. The shift was also seen in the presence of a choline-substituted low Na+ saline. Enhancement of a slow inward Ca2+ current is a possible mechanism for the decrease in Ca2+ spike threshold; however, it is impossible to use the Ca2+ spike as an assay when testing the effects of blocking Ca2+ conductances. Therefore, we studied the influence of CGs on the membrane current-voltage (I-V) curve, since persistent voltage-dependent conductances appear as nonlinearities in the I-V plot obtained under current clamp.(ABSTRACT TRUNCATED AT 400 WORDS)     

Current-evoked transcellular K+ flux in frog retina

1. Changes in extracellular K+ concentration (delta[K+]o) evoked by electrical current were measured with K+-selective microelectrodes (K-ISMs) in the retina of the frog eyecup. 2. In the superfusate at 20 microns above the inner limiting membrane (ILM), current-evoked delta[K+] was a function of current polarity and strength; its amplitude decreased as the K-ISM was moved higher above the ILM. Responses were similar whether measured with K-ISMs containing the Corning exchanger or a valinomycin-based liquid membrane. No current-evoked delta[Ca2+] could be detected with Ca-selective microelectrodes (Ca-ISMs). 3. Within the retina, a complex spatiotemporal profile of current-evoked delta[K+]o was observed. Strophanthidin abolished responses in the proximal retina, but had little effect on the response in the superfusate. A blocker of K+ channels (Ba2+) depressed responses in the superfusate, but not in the proximal retina. 4. Quantitative analysis of these responses indicates a transport number for K+ of 0.18 at onset of current, and that decreases over a few seconds. In contrast, a transport number of approximately 0.01 is predicted from the expected ionic concentrations within extracellular space. 5. These findings are compatible with the delta[K+] above the ILM being due to transcellular movement of K+ through Müller cells. The results suggest that K+ spatial buffering may be particularly potent in the retina. Furthermore, determinations of tissue characteristics by passage of electrical current must take into account that at least 17% of the current does not travel through extracellular space.     

Activity-related extracellular potassium transients in the neonatal rat spinal cord: an in vitro study

Transient increases and decreases in extracellular potassium (delta[K+]o) were recorded from the gray matter of hemisected, neonatal rat spinal cords isolated from 3, 4, 9- and 10-day-old pups. delta[K+]o were evoked in both the ventral and dorsal regions of the gray matter by electrical stimulation. In the ventral horn, repetitive stimulation of the ventral root was required to elicit detectable delta[K+]o. By contrast, single dorsal root stimuli evoked clear delta[K+]o. In the dorsal horn, single orthodromic stimuli elicited delta[K+]o as large as 4-5 mM from a baseline of 4.5 mM. With repetitive stimulation the [K+]o reached, but never exceeded, a ceiling of 10-11 mM. Undershoots were seen only after repetitive stimulation. Spontaneous delta[K+]o were observed in the ventral horn and were well correlated with ventral root activity. Spontaneous delta[K+]o were rare in the dorsal cord, but were recorded after bath application of apamin or tetraethylammonium. The magnitude and distribution of evoked K+ transients and postsynaptic components of the evoked field potential were well correlated in both the dorsal and the ventral gray matter. delta[K+]o were reversibly blocked by 1 mM CdCl2 in the bath and diminished by 1 mM BaCl2. Bath application of mephenesin, apamin or tetraethylammonium diminished evoked delta[K+]o in a stimulus-dependent manner. In apamin and tetraethylammonium, decreases from control responses were largest with high intensity stimulation, the opposite was the case with mephenesin. These results are interpreted in terms of the spinal circuits activated by high- and low-intensity electrical stimulation. We conclude that activity-related delta[K+]o in neonatal spinal cord are large enough to modulate neuronal electrical activity and the [K+]o is well regulated compared to other immature CNS regions studied. Thus, local increases in [K+]o may, by modulating neuronal activity, play a role in neonatal spinal cord developmental processes.     

Use-dependent depression of IPSPs in rat hippocampal pyramidal cells in vitro

We have used intracellular recording techniques to study the use-dependence of evoked inhibitory postsynaptic potentials (IPSPs) in rat CA1 hippocampal pyramidal cells. We determined reversal potentials and conductance changes associated with IPSPs and responses to directly applied gamma-aminobutyric acid (GABA). The IPSP depression could be seen after a single conditioning stimulus. This depression appeared to be due primarily to a 50% decrease in IPSP conductance (gIPSP). Trains of stimulating pulses (50 pulses at 5 or 10 Hz) produced more pronounced effects than a single conditioning pulse. Suprathreshold repetitive stimulation of stratum radiatum (SR) produced epileptiform burst firing and greater depression of IPSPs than did alvear (ALV) or subthreshold SR stimulation. During suprathreshold SR stimulation the IPSP was nearly abolished and the membrane potential could become less negative than the resting potential. A masking effect of facilitated depolarizing potentials on IPSPs was unlikely since IPSPs accompanied by little or no depolarizing potential were also depressed by SR trains. The 75% reduction in IPSP conductance found after repetitive stimulation confirmed that an overlapping conductance was not responsible for the depression of the IPSP. The GABA-induced conductance increase was not depressed by identical trains. Trains of stimulation induced depolarizing shifts in equilibrium potentials for the IPSP (EIPSP) and GABA (EGABA) of approximately 10 mV. These shifts were always greater after SR trains than after ALV trains. Simultaneous recordings of membrane potential and extracellular potassium concentration ([K+]o) with K+-sensitive microelectrodes revealed a direct correlation between the two during a stimulus train. Membrane potential depolarized as much as 18 mV from the peak of the IPSP and [K+]o could increase to a maximum of 10 mM during some trains. A depressant effect (of approximately 50%) of K+ on IPSPs was demonstrated by brief pressure ejection of K+ near the soma. We conclude that repetitive stimulation depresses gIPSP and shifts EIPSP in the depolarizing direction. Whereas gIPSP began to decline after a single conditioning pulse, the additional depression of IPSPs produced by stimulus trains was due in large part to shifts in EIPSP. Depression of gIPSP was not due to desensitization or block of ionic conductances, since gGABA was not reduced. The EIPSP may change as a result of increases in [K+]o.     

Epileptiform activity induced by low chloride medium in the CA1 subfield of the hippocampal slice

1. Extracellular and intracellular recordings and measurements of the extracellular concentration of free K+ ([K+]o) were performed in the CA1 subfield of the rat hippocampal slice during perfusion with artificial cerebrospinal fluid (ACSF) in which NaCl had been replaced with equimolar Na-isethionate or Na-methylsulfate (hereafter called low Cl- ACSF). 2. CAl pyramidal cells perfused with low Cl- ACSF generated intracellular epileptiform potentials in response to orthodromic, single-shock stimuli delivered in stratum (S.) radiatum. Low-intensity stimuli evoked a short-lasting epileptiform burst (SB) of action potentials that lasted 40-150 ms and was followed by a prolonged hyperpolarization. When the stimulus strength was increased, a long-lasting epileptiform burst (LB) appeared; it had a duration of 4-15 s and consisted of an early discharge of action potentials similar to the SB, followed by a prolonged, large-amplitude depolarizing plateau. The refractory period of the LB was longer than 20 s. SB and LB were also seen after stimulation of the alveus. 3. Variations of the membrane potential with injection of steady. DC current modified the shape of SB and LB. When microelectrodes filled with the lidocaine derivative QX-314 were used, the amplitudes of both SB and LB increased in a linear fashion during changes of the baseline membrane potential in the hyperpolarizing direction. The membrane input resistance, as measured by injecting brief square pulses of hyperpolarizing current, decreased by 65-80% during the long-lasting depolarizing plateau of LB. 4. A synchronous field potential and a transient increase in [K+]o accompanied the epileptiform responses. The extracellular counterpart of the SB was a burst of three to six population spikes and a small increase in [K+]o (less than or equal to 2 mM from a resting value of approximately 2.5 mM). The LB was associated with a large-amplitude, biphasic, negative field potential and a large increase in [K+]o (up to 12.4 mM above the resting value). Changes in [K+]o during the LB were largest at the border between S. oriens and S. pyramidale. This was also the site where the field potentials measured 2-5 s after the stimulus attained their maximal amplitude. Conversely, field potentials associated with the early component of the LB or with the SB displayed a maximal amplitude in the S. radiatum. 5. Spontaneous SBs and LBs were at times recorded in the CA1 and in the CA3 subfield.(ABSTRACT TRUNCATED AT 400 WORDS)     

Nonsynaptic epileptogenesis in the mammalian hippocampus in vitro. I. Development of seizurelike activity in low extracellular calcium

Epileptiform activity induced in rat hippocampal slices by lowering extracellular Ca2+ concentration ([Ca2+]o) was studied with extracellular and intracellular recordings. Perfusing the slices with low Ca2+ (less than or equal to 0.2 mM) or EGTA-containing solutions blocked the synaptic responses of hippocampal pyramidal cells (HPCs). Despite the block, spontaneous paroxysms, termed seizurelike events (SLEs), appeared in the CA1 area and then recurred regularly at a stable frequency. Transient hypoxia accelerated their development and increased their frequency. When [Ca2+]o was raised in a stepwise manner, the SLEs disappeared at 0.3 mM. With extracellular recording from the CA1 stratum pyramidale, a SLE was characterized by a large negative shift in the field potential, which lasted for several seconds. During this period a large population of CA1 neurons discharged intensely and often in synchrony, as concluded from the frequent appearance of population spikes. Synchronization, however, was not a necessary precursor for the development of paroxysmal activity, but seemed to be the end result of massive neuronal excitation. The cellular counterpart of a SLE, as revealed by intracellular recording from HPCs in the discharge zone of the paroxysms, was a long-lasting depolarization shift (LDS) of up to 20 mV. This was accompanied by accelerated firing of the neuron. A prolonged after-hyperpolarization succeeded each LDS and arrested cell firing. Brief (approximately 50 ms) bursts were commonly observed before LDS onset. Single electrical stimuli applied focally to the stratum pyramidale or alveus evoked paroxysms identical to the spontaneous SLEs, provided they surpassed a critical threshold intensity. Subthreshold stimuli elicited only small local responses, whereas stimuli of varied suprathreshold intensities evoked the same maximal SLEs. Thus the buildup of a SLE is an all or nothing or a regenerative process, which mobilizes the majority, if not all, of the local neuronal population. Each SLE was followed by absolute and relative refractory periods during which focal stimulation was, respectively, ineffective and less effective in evoking a maximal SLE. In most slices the spontaneous SLEs commenced at a "focus" located in the CA1a subarea (near the subiculum). SLEs evoked by focal stimulation arose near the stimulating electrode. From their site of origin the paroxysmal discharges spread transversely through the entire CA1 area at a mean velocity of 1.74 mm/s. Consequently, the discharge zone of a SLE could encompass for several seconds the entire CA1 area.(ABSTRACT TRUNCATED AT 400 WORDS)     

An N-methyl-D-aspartate receptor-independent excitatory action of partial reduction of extracellular [Mg2+] in CA1-region of rat hippocampal slices

Partial reduction of [Mg2+]o from 2 to 1 mM markedly enhanced neuronal responses evoked by Schaffer collateral-commissural fiber stimulation in the CA1-region of rat hippocampal slices. The amplitude of extracellular population potentials recorded in the CA1-pyramidal cell layer and maximum dV/dt of extracellular population EPSP's recorded in the CA1-pyramidal apical dendritic layer were both increased. However, unlike findings from slices where Mg2+ was completely removed from the bathing medium, there was no spontaneous or evoked epileptiform activity, and the N-methyl-D-aspartate (NMDA) receptor antagonist 2-amino-5-phosphonovalerate (2-APV) did not antagonize the enhancement of evoked responses. These results indicate that, in addition to the participation of NMDA receptors in the epileptiform activity observed when Mg2+ is completely removed from the bathing medium, there is also an NMDA receptor-independent excitatory action of partial reduction of [Mg2+]o in hippocampal slices.     

Contribution of the receptor and basolateral membranes to the resting potential of a frog taste cell

Contributions of the receptor and basolateral membranes to the resting potential in bullfrog taste cells were studied by replacing the superficial and interstitial fluids of the tongue by various salines. When the interstitial K+ concentration ([K+]0) was increased to 100 mM, the resting potential decreased by 45%. A similar increase in superficial [K+]0 decreased the resting potential by 15%. A simultaneous increase in both superficial and interstitial [K+]0 to 100 mM decreased the resting potential by 60%. Total removal of Na+ from either the superficial or interstitial fluid increased the resting potential by 40%. Ouabain (10(-4) M) in the interstitial fluid decreased the resting potential by 30%, while the drug in the superficial fluid had no effect. Amiloride (10(-3) M) in the superficial fluid hyperpolarized the cells to 145%, while the drug in the interstitial fluid caused no change in the resting potential. Ca2+-free superficial saline reduced the resting potential to 75%. Interstitial Ca2+ did not affect the resting potential. Total removal of either superficial Cl- or interstitial Cl- did not change the resting potential. These results suggest: 1) Na+ and K+ move across the receptor and basolateral membranes of the taste cell down their electrochemical gradients, 2) Na+ is extruded from the taste cell by the Na-K pump which exists only in the basolateral membrane, 3) the resting potential of a frog taste cell consists of the diffusion potentials of Na+ and K+ across the receptor and basolateral membranes, and the potential resulting from the activity of the electrogenic Na-K pump in the basolateral membrane.     

Epileptiform activity induced by changes in extracellular potassium in hippocampus

Using extra- and intracellular recording techniques, we investigated the induction and frequency modulation of spontaneous epileptiform activity produced by changes in the concentration of extracellular potassium ([K+]o). This paper describes a quantitative relationship between [K+]o and the frequency of spontaneously occurring epileptiform events. Recordings were made from the CA3 subfield of the rat in vitro hippocampal slice preparation. Intracellular microelectrodes were filled with 2 M Cs2SO4 and connected to a 3-kHz, time-share, single-electrode current- and voltage-clamp device. The frequency of spontaneous epileptiform (interictal) discharges was determined from extracellular recordings as a function of [K+]o. Current- and voltage-clamp techniques were used to characterize the intracellular correlate of these epileptiform events. The frequency of bicuculline-induced spontaneous epileptiform discharges was dependent on [K+]o. Below 4 mM [K+]o, spontaneous discharges occurred sporadically in the presence of 10 microM bicuculline. Increasing [K+]o from 5 to 10 mM caused a fivefold increase in the rate of spontaneous discharges. Spontaneous epileptiform discharges also occurred in the absence of bicuculline when [K+]o was increased above 6.5 mM. The rate of these discharges was dependent on [K+]o in much the same way as the discharges induced by bicuculline. For any given [K+]o concentration greater than 6.5 mM, however, the resultant discharge rate was faster than that obtained when bicuculline was present in the bathing solution. Simultaneous intra- and extracellular recordings revealed that the spontaneous high-[K+]o-induced interictal discharge was accompanied by a large depolarization of the membrane potential that appeared similar to the paroxysmal depolarizing shift (PDS) seen with other convulsants. The intracellularly recorded event fulfilled the criteria for a synaptically mediated PDS. The waveform of the PDS was complex and dependent on the membrane potential. When the membrane potential was held at 0 mV, spontaneously occurring hyperpolarizing potentials were noted during the inter-PDS interval. These events were blocked by picrotoxin or bicuculline and were probably spontaneous inhibitory postsynaptic potentials. The complexity of the PDS waveform suggested that more than one synaptic conductance was involved in the generation of the PDS. The mean measured reversal potential of the depolarizing phase was -10.7 mV. Voltage-clamp techniques were used to measure the conductance underlying the depolarizing phase of the high-[K+]o-induced PDS. The mean measured conductance was 51.5 nS, with a reversal potential of -7.9 mV.(ABSTRACT TRUNCATED AT 400 WORDS)     

Properties of the larval neuromuscular junction in Drosophila melanogaster.

The anatomy and physiology of the Drosophila larval neuromuscular junction were studied. 2. The dependence of muscle resting potentials on [K+]o and [Na+]o follows the Goldman-Hodgkin-Katz equation (PNa/PK=0-23). Chloride ions distribute passively across the membrane. 3. The mean specific membrane resistance of muscle fibres is 4-3 X 10(3) omega cm2, and the mean specific membrane capacitance is 7-1 muF/cm2. The muscle fibre is virtually isopotential. 4.Transmitter release is quantal. Both the miniature excitatory junctional potential and the evoked release follow the Poisson distribution. 5. Transmitter release depends on approximately the fourth power of [Ca2+]o. If Sr2+ replaces Ca2+, it depends on approximately the fourth power of [Sr2+]o. Mg2+ reduces transmitter release without altering the fourth power dependence on [Ca2+]o.     

Inhibitory role of dentate hilus neurons in guinea pig hippocampal slice

1. Current and voltage-clamp recording of CA3/CA4 pyramidal neurons, hilar neurons, and granule cells or pairs of these neurons were used to study the generation of Cl-dependent and K-dependent inhibitory postsynaptic potentials (IPSPs) in the guinea pig hippocampal slice preparation. 2. A sequence of an early Cl-dependent and a late K-dependent IPSP was evoked in CA3 neurons by electrical stimulation from the stratum moleculare of the dentate gyrus, the hilus, and the stratum oriens/alveus. Blockade of glutamatergic excitation by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX, 10 microM) and D(-)-2-amino-5-phosphonovaleric acid (APV, 30 microM) abolished IPSPs evoked from the stratum moleculare of the dentate gyrus, but IPSPs could still be evoked from the hilus and the stratum oriens/alveus. 3. Repetitive giant IPSPs, which consisted of Cl-dependent and K-dependent components, were evoked by bath application of 4-aminopyridine (4-AP, 10-50 microM) in CA3 neurons and in granule cells. Giant IPSPs were blocked by bath-applied tetrodotoxin (TTX). In addition, 4-AP hyperpolarized CA3 neurons in a Cl-dependent and picrotoxin-sensitive way. 4. Focal application of TTX to the dentate gyrus or the hilus considerably reduced the amplitude of giant IPSPs evoked by 4-AP in CA3 neurons. In hilar neurons, 4-AP evoked repetitive bursts, eventually, but not necessarily intermingled with giant IPSPs. Bursts were observed in hilar neurons in presence as well as absence of CNQX and APV. 5. In paired recordings, bursts in hilar neurons induced by 4-AP occurred simultaneously to giant IPSPs in granule cells and CA3 neurons, and giant IPSPs in granule cells occurred simultaneously to giant IPSPs in CA3 neurons. Blockade of glutamatergic excitation by CNQX and APV did not abolish this synchrony. 6. 4-AP-evoked Cl- and K-dependent IPSPs were, unlike electrically evoked IPSPs, not strictly coupled: some 20% of large IPSPs and up to 90% of small IPSPs were either Cl or K dependent. In granule cells K-dependent components either preceded or followed Cl-dependent components. 7. K-dependent IPSPs only could be evoked in CA3 neurons by focal application of 4-AP (1 mM) to the hilus, the stratum lacunosum moleculare or the stratum pyramidale. Wash out of Ca for 15-20 min blocked the Cl-dependent but not the K-dependent component of giant IPSPs evoked by bath-applied 4-AP.(ABSTRACT TRUNCATED AT 400 WORDS)     

Role of extracellular space in hyperosmotic suppression of potassium-induced electrographic seizures

1. Focal electrographic seizures arose in the CA1 region of rat hippocampal slices bathed in elevated (8.5 mM) external potassium [( K+]o). High [K+]o also induced spontaneous interictal bursts that originated in area CA3 and propagated to CA1. To examine the contribution to electrographic seizure initiation of excitatory mechanisms that are influenced by extracellular volume, we studied the effect of hyperosmotic expansion of interstitial volume on seizure occurrence, interictal bursts, and excitatory synaptic transmission. The tissue electrical resistance was also measured leading up to and during seizures. 2. Media made 5-30 mosmol/kg hyperosmotic by addition of agents restricted to the extracellular space (mannitol, sucrose, raffinose, L-glucose, dextran) rapidly and reversibly abolished [K+]o-induced spontaneous CA1 seizures in 86% of slices tested. However, similar increases in osmolality effected by agents that access the intracellular compartment (D-glucose, glycerol) did not influence electrographic seizure occurrence. Hyperosmotic changes with plasma membrane impermeable compounds, but not permeable compounds, produced significant concentration-dependent decreases (1-10%) in the electrical resistance of CA1 stratum pyramidale. Because tissue resistance is proportional to extracellular volume, these results suggest that hyperosmotic suppression of electrographic seizures is associated with expansion of the extracellular space in hippocampal slices. 3. Measurement of electrical resistance of the CA1 stratum pyramidale during spreading depression and electrographic seizure revealed an increase in tissue resistance to 122% and 108% of control, respectively. Furthermore, a slight (approximately 2%) but significant increase in electrical resistance gradually occurred over the 20 s immediately preceding seizure generation. The observed increase in tissue resistance suggests extracellular space is decreased during these events. 4. Hyperosmolality did not alter CA3 interictal burst frequency. However, burst intensity, estimated from the total length of the burst waveform, was significantly reduced in both the CA3 (83% control) and CA1 region (67% control) when osmotic changes were imposed by plasma membrane impermeant compounds. Additionally, media made hypoosmotic by removal of 7.5 mM NaCl reversibly increased burst intensity. 5. High [K+]o potentiated excitatory synaptic transmission and excitatory postsynaptic potential (EPSP) spike coupling.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of kindling on potassium-induced electrographic seizures in vitro

The properties of high [K+]o-induced spontaneous bursting and electrographic seizures in hippocampal slices prepared from rats subjected to kindling from either the lateral entorhinal cortex or the angular bundle were compared to those in control slices. Kindling enhanced the frequency of K+-induced burst-firing in the CA3 region and the duration of triggered bursts in the dentate gyrus, as previously reported. However, kindling had no influence on the characteristics or occurrence of electrographic seizures in the CA1 region of slices bathed in elevated [K+]o. In addition, the development of electrographic seizures in slices from control animals did not require a preconditioning period of burst input from the CA3 region.     

Activity-evoked increases in extracellular potassium modulate presynaptic excitability in the CA1 region of the hippocampus

1. The effects of stimulus-evoked potassium release on the excitability of presynaptic axons were studied in the rat hippocampal slice preparation. Extracellular stimulation and recording in the stratum radiatum of CA1 yielded a characteristic field potential corresponding to the compound action potential of nonmyelinated afferents and subsequent postsynaptic activation of pyramidal cells. 2. Repetitive stimulation (1 s; 2-100 Hz) produced biphasic changes in the excitability of the afferents. Initial responses showed increased conduction velocity and variably increased amplitude; subsequent responses showed progressively decreasing conduction velocity and amplitude tending toward conduction block. Decreases in excitability were maximal at the end of stimulation and were more pronounced with higher stimulation frequencies. 3. When synaptic transmission was abolished with superfusate containing elevated [Mg2+] (6 mM) and decreased [Ca2+] (0.25 mM), kynurenic acid (1 mM), or adenosine (100 microM), the ability of the fibers to follow repetitive stimulation was enhanced, as indicated by a reduction in amplitude decrement of the presynaptic volley. The decrease in conduction velocity at the end of stimulation was less than half that obtained with intact postsynaptic activity. 4. Concomitant with changes in the excitability of CA1 afferents, the concentration of extracellular potassium ( [K+]o) increased up to 7 mM, as recorded in the stratum radiatum with potassium ion-sensitive microelectrodes. When postsynaptic activity was blocked, activity-evoked rises in [K+]o were reduced to less than 25% of their former value. This suggests that activity-evoked increases in [K+]o derive predominantly from postsynaptic elements. 5. Superfusion of solutions containing elevated [K+] produced biphasic changes in the excitability of CA1 afferents that were qualitatively similar to those produced by repetitive stimulation. Elevated [K+]o below 6 mM produced increased excitability, whereas [K+]o above 6 mM yielded decreased excitability. 6. These results demonstrate that in the CA1 region of the hippocampus, significant rises in [K+]o occur with activity and derive predominantly from postsynaptic elements. The conduction properties of CA1 afferents are sensitive to the level of [K+]o, whether altered artificially or by activity. These effects may constitute a mechanism of postsynaptic modulation of presynaptic conduction operating within a broad range of afferent firing frequencies in the hippocampus.     

Metabotropic receptor-mediated Ca2+ signaling elevates mitochondrial Ca2+ and stimulates oxidative metabolism in hippocampal slice cultures

Metabotropic receptors modulate numerous cellular processes by intracellular Ca2+ signaling, but less is known about their role in regulating mitochondrial metabolic function within the CNS. In this study, we demonstrate in area CA3 of rat organotypic hippocampal slice cultures that glutamatergic, serotonergic, and muscarinic metabotropic receptor ligands, namely trans-azetidine-2,4-dicarboxylic acid, alpha-methyl-5-hydroxytryptamine, and carbachol, transiently increase mitochondrial Ca2+ concentration ([Ca2+]m) as recorded by changes in Rhod-2 fluorescence, stimulate mitochondrial oxidative metabolism as revealed by elevations in NAD(P)H fluorescence, and induce K+ outward currents as monitored by rapid increases in extracellular K+ concentration ([K+]o). Carbachol (1-1,000 microM) elevated NAD(P)H fluorescence by 相似文献